Security and public safety application for a mobile device

ABSTRACT

In a plurality of described embodiments, various modules of an application for a client device may operate to enhance personal security for an individual user, as well as public safety in general. A Blue-Phone-in-Pocket (bPip) module operates comparable to, but more effectively than, the traditional college campus blue light phone. When the user of the module toggles a button on the GUI of his/her smartphone, the App may instantly record and transmit key information to a command center, which operates to provide assistance to the student, at their current location, without requiring the student to relocate to one of the tradition blue light phone fixtures. A tracking module permits the student or other user to be tracked by his/her device until safely reaching a travel destination. The person may trigger an alarm if endangered during the trip, which may prompt a respond from local law enforcement, and other assigned individuals.

CROSS REFERENCE TO RELATED APPLICATIONS

This application claims priority on U.S. Provisional Application Ser. No. 62/029,680 filed on Jul. 28, 2014, the disclosures of which are incorporated herein by reference.

FIELD OF THE INVENTION

The present invention relates to improvements in security and public safety systems, and more particularly to a platform of mobile solutions that are devised to improve an individual's ability to be warned/informed and to warn others of hazards or events, and to request assistance that may be provided in many different forms.

BACKGROUND OF THE INVENTION

Mobile applications (“Apps”) for a user's smart phone or other mobile computing devices (e.g., iPad, Kindle, etc.), have gained popularity, particularly with millennials, who tend to be more technology savvy, and exhibit a greater willingness to improve their lives through the use of new programs and devices. For example, there are a number of Apps related to personal security and safety that are available for the iPhone, and some for Android as well, many of which are geared to college students. Some of these include: Bsafe, Guardly, Watch Over Me, StaySafe, OnWatch, and Circle of 6. Each of these Apps provide some narrow safety enhancing functionality, which typically is directed to alerting family members and/or friends about a perceived threat or an ongoing unsafe situation. Some of these Apps include GPS tracking and transmitting of the user's location, and others include automatic sending of emergency notifications if the cell phone user fails to reach their entered destination within the allotted time period.

The next-generation platform of the present invention may incorporate similar functionality, but is further adapted to include many other features that contribute to the user's safety and situational awareness, and the ability to better interact in the community to further contribute to such safety and security for themselves and for others as well.

SUMMARY OF THE INVENTION

The present invention may be in the form of a mobile web application or a device specific native application that is directed to enhancing public safety and security, through the use of a plurality of different modules, many of which can be easily modified and customized for customer specific applications.

The array of functionality offered by the application may include the following, at an upper level of its functional hierarchy:

-   -   GPS Location-based Monitoring of a Police Scanner;     -   User Chat by Location;     -   Provision of Crime Data, based on GPS location and preferences;     -   A Bulletin Alert Module to provide a scrolling list of relevant         information that the client desires to push to the user, or the         user desires to receive;     -   A Track Me Module with a Trip Duration Timer that sounds an         alarm if not disarmed by passcode or biometric means within the         allotted time;     -   A Blue-Phone-in-Pocket (bPip) module;     -   A panic button configured to send an instant message with         minimal user input that may be customized;     -   An Incident Reporting Module;     -   A Person of interest Tracker that permits the user to identify a         specific person in a picture or video by drawing an outline         around them, which can be sent to the main system which then can         be imported into other third party systems;     -   An I.D. Verification Module;     -   A mobile profiler that permits the user to create a composite         image that represents an individual they are trying to describe;     -   A Drone Assist Module usable during live pursuit for the         tracking of individuals, by harvesting information broadcast by         their mobile device, and with continuous tracking capability         over varying geographical configurations through hand-off of         information to one or more drones;     -   Accessibility of functionality using Google Glass;     -   Wearable devices such as a security vest that may be coupled to         the App to communicate critical data to a control center, such         as the transmission of the person's vital signs (heart rate,         reparation rate, etc.) and impact data;     -   A Bail Check-In Module where bail is conditioned upon the         suspect using the App. to periodically check in and respond to         random check-in requests;     -   A Backend Engine;     -   A multi-functional pre-processing information module, which         includes transcoding of video and audio, originally captured for         storing high resolution copy, to a high efficiency format for         uploading of the data; and     -   A fan experience module.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a graphical illustration of the various functionality offered by the next generation security and public safety platform of the present invention.

FIG. 2 illustrates the icon that may be used to launch the App of the present invention, as it appears on the display of an exemplary smart phone.

FIG. 3 illustrates the smart phone of FIG. 2, and the function buttons available to the user after selecting the icon of FIG. 1 to launch the App of the present invention.

FIG. 4 illustrates the smart phone of FIG. 3, showing one of the screens of the Police Scanner module, in which the user may monitor one of the frequencies used by the local police department.

FIG. 5 illustrates the smart phone of FIG. 3, showing one of the screens of the Crime Data module, in which the user is alerted of being within a threshold distance of a high crime area.

FIG. 6 illustrates the smart phone of FIG. 3, showing a first screen of the “Track Me Module,” which permits the user to enter a starting point and a destination for a trip.

FIG. 7 illustrates the smart phone of FIG. 6, showing a second screen of the “Track Me Module,” after the user has entered a starting point and a destination for the trip, and is being prompted to arm the feature to begin the trip.

FIG. 8 illustrates the smart phone of FIG. 7, showing a third screen of the “Track Me Module,” after the user had entered a starting point and a destination for the trip, and had armed the feature to begin tracking.

FIG. 9 illustrates an alternate embodiment of the “Track Me Module” shown in FIG. 6, and additionally includes a timer option.

FIG. 9A shows the screen of the smart phone of FIG. 9, but after the user has selected the timer option, and when only 19 minutes remain of the time that was originally entered.

FIG. 9B shows the screen of the smart phone of FIG. 9A, but when only 3 seconds remain of the time that was originally entered.

FIG. 9C shows the screen of the smart phone of FIG. 9A, but when only zero time remains of the time that was originally entered.

FIG. 9D shows the screen of the smart phone of FIG. 9A, but after the user has toggled the panic button.

FIG. 10 is a schematic illustration showing an exemplary computing unit capable of being programmed by the instructions of the software of the present invention, and which may include cellular phones, personal computers, and other mobile smart devices.

DETAILED DESCRIPTION OF THE INVENTION

The platform of the present invention can be easily modified and customized fbr customer specific applications, and may be in the form of a mobile web application or a device specific native application. As used on a client device, such as the exemplary smart phone 10 shown in FIG. 2, the functionality of the platform 11 (see FIG. 1) may be accessed by tapping on the corresponding icon, which is an application (“App”) labeled therein as “See It-Send It.” Accessing the platform through the icon may result in the display of function buttons, as seen for the smart phone of FIG. 3. The array of functionality offered by the platform may include the following, at an upper level of its functional hierarchy:

-   -   GPS Location-based Monitoring of a Police Scanner;     -   User Chat by Location;     -   Provision of Crime Data, based on GPS location and preferences:     -   A Bulletin Alert Module to provide a scrolling list of relevant         information that the client desires to push to the user, or the         user desires to receive;     -   A Track Me Module with a Trip Duration Timer that sounds an         alarm if not disarmed by passcode or biometric means within the         allotted time;     -   A Blue-Phone-in-Pocket (bPip) module;     -   A panic button configured to send an instant message with         minimal user input that may be customized;     -   An Incident Reporting Module;     -   A Person of Interest Tracker that permits the user to identify a         specific person in a picture or video by drawing an outline         around them, which can be sent to the main system which then can         be imported into other third party systems;     -   An I.D. Verification Module;     -   A mobile profiler that permits the user to create a composite         image that represents an individual they are trying to describe;     -   A Drone Assist Module usable during live pursuit for the         tracking of individuals, by harvesting information broadcast by         their mobile device, and with continuous tracking capability         over varying geographical configurations through hand-off of         information to one or more drones;     -   Accessibility of functionality using Google Glass;     -   Wearable devices such as a security vest that may be coupled to         the App to communicate critical data to a control center, such         as the transmission of the person's vital signs (heart rate,         reparation rate, etc.) and impact data;     -   A Bail Check-In Module where bail is conditioned upon the         suspect using the App. to periodically check in and respond to         random check-in requests;     -   A Backend Engine;     -   A multi-functional pre-processing information module, which         includes transcoding of video and audio, originally captured for         storing high resolution copy, to a high efficiency format for         uploading of the data; and     -   A fan experience module.

Each of the above modules of functionality offered by the platform of the present invention are discussed in detail hereinafter.

The client device of the user that may provide the above functionality of the App may communicate with server system 264 that may provide task management and device tracking functionality, and which can be deployed at one or more data centers in one or more geographic locations

GPS Location-Based Monitoring of the Police Scanner:

This module of the platform is configured to harvest radio transmissions and information in the same manner as a police scanner. The module may auto associate the mobile user's location with the local police band broadcast, and may therefore be constructed to provide the user with the capability to only listen, by listening to the radio broadcasts on those specific frequencies, as shown in FIG. 4.

Alternatively, the module may also include a push-to-talk feature, which may utilize the voice capability of the mobile device to thereby allow the user to participate in conversations with other mobile users of the App. The programming of the application may emulate push-to-talk functionality over the cell network for each of the participating App users. Such conversations may be based on the user's GPS location, and may be limited to a radial distance therefrom, so that the user may be able to monitor, for example, the reports being made by the police officers dispatched to a highway accident that has caused a traffic back-up stretching a great distance. Users responding to similar incidents may also be grouped together. Therefore, drivers who may have no visual contact with the accident scene, but wish to be apprised of its severity and any movement of the accident vehicles, which might suggest that traffic will soon begin to proceed normally, may use the functionality to contact other users who may be in close proximity to the accident. This push-to-talk feature may also be configured to interface with conventional radio communications (e.g., short wave radio). These conventional radio communications may be captured by a receiver, and be processed over a server, for re-encoding the audio for transmission over the cell network to the mobile device of the user(s).

In addition, the police scanner module may be configured to run audio analytics. The server may be receiving and recording each of the police band channels, and may thereby be capable of picking out and identifying key words that are spoken on the local channel, and which would be in proximity to the user of the App. For example, as seen in FIG. 4, the user may have an interest in any reports about their car that may have been stolen, and may thus enter the words “stolen vehicle,” or “stolen” and “vehicle.” The user may utilize the App to be apprised of any progress with respect to any event of interest to them. It may also be very beneficial for a community at large, such as where there may be on-going criminal activity like the pursuit of the Boston Marathon bombers throughout the surrounding area, or where first responders may be on scene, as in the case of a natural disaster (e.g., hurricanes, volcanic eruption) or other disaster (e.g., 911, a commercial airplane crash, etc.).

User Chat by Location

An extension of the above functionality is provided by the ability to generally engage in localized chat with other such users who are in proximity to that App user's mobile device. The module may provide settings permitting adjustment to the maximum distance away that such other users may be distant therefrom, to be able to participate in the conversation. The threshold distance may be set according to the user's preferences, which may vary from time to time according to the particular situation or need. The module may determine which other App users are within the maximum distance. The module may also provide an interactive map showing the other users of the App, and the positioning thereon of their mobile device through the use of respective icons. The conversations may be textual or oral. Where textual conversations occur, they may be delineated on the map, and may be associated to the other App user's icon, using speech bubbles, so that the user can see all of the comments, and location where the person making the comments was positioned on the map at that time.

Provision of Crime Data, Based on GPS Location and Preferences:

This module may also be configured to provide access into one or more crime databases. The information in the crime database(s) may be sorted by location. The user of this functionality may request crime statistics and other data for his/her current location. In addition, the user may set his/her preferences so that the module will use the data to dynamically alert the user of the threat level at the location that he/she is currently occupying, based on the local crime statistics. For example, if the person is walking throughout the city of Chicago, and approaches or enters within a threshold distance (e.g., 0.10 miles) of an area in which there tends to be a greater prevalence of crime (each category of which may be delineated on the map), the module may periodically send a text notification to the device while the person remains in the higher threat level areas. The user may adjust their personal preferences to change the threshold distance to be a value other than the default of one-tenth of a mile. The text notification may be accompanied by an aural alarm, and/or a vibration alert to ensure that the person is positively notified of the potentially hostile surroundings, so that they may be more vigilant.

This may serve to aid a tourist to the city, who is unfamiliar with the various neighborhoods. The module may also contain databases for cities in other countries, which may assist travelers who are on vacation abroad to help them remain safe while exploring among people who may not even speak the same language.

A Bulletin Alert Module:

A bulletin alert module may be used to supplement the information that may already be received by the user of the mobile device, particularly from the crime data base. The Bulletin module may alert the user as to any information or situations that that the client wants to push to the user. The bulletins may be in the form of a scrolling list presented at the top of the mobile App, which may be displayed at all times while the user is using the application on their device.

Links may be provided within the bulletins to permit the user to drill down into the information presented therein. The links may be configured to display the following information:

-   -   Pictures—such as for missing persons or wanted person.     -   Video—such as a news video clip or informational video with         details of a message.     -   Website links—such as links to external sites for additional         information.         “Track Me” Module with a Trip Duration Timer

This module may allow the App user to be tracked for a specific amount of time and for a specific route. If the user exceeds the time/distance parameters, then the device will set off a panic alarm.

To initiate the functionality, the App user may first tap on the “Track Me” Module button shown in FIG. 3, which may result in the display of the screen shown in FIG. 6. The screen may permit the entering by the user of a starting point and a destination for the trip. The module may utilize the person's current location for the starting point of the trip by selecting “Current Location,” as the current location of the user's device is generally always known. The user may also key in a starting address, which may be different that his/her current location, because the user may anticipate beginning a walking trip, perhaps after getting off of some form of public transportation. The App user may prefer to immediately begin walking, and not loiter at the stop to enter the address, after the bus/train/car leaves the area. The destination address may also be entered, or it may be retrieved from the user's history, by selecting “Previous Location.” Once the starting point for the trip and the destination have been identified, the user may select the mode of transportation, by choosing the car icon, the bike icon, or the hiker icon, after which the screen may change to be as shown in FIG. 7. The user in this example may have chosen the current location as the starting point, and the corner of Hirsh Street and North St. Louis Ave as the destination, and may have selected the hiker icon because they intend to walk to the destination. The car icon and the bike icon may still be displayed in the screen of FIG. 7, to give the user the option to change the mode of transportation, which would recalculate the allocated walking time to instead be the corresponding driving time, according to the remaining distance (e.g., where the person may have made an unplanned stop that required a large amount of time, and the person may decide to take a bus instead of walking the remaining distance).

The module may identify a preferred route, which may be based on distance and safety (i.e., based on crime rates in the relevant areas), as well as the total distance of the route and an allotted time for the walk. The module may provide user controls to “arm” and “disarm” the panic notifications associated with the trip parameters. When the user begins the trip, he/she may arm the feature, and their progress will be monitored, both as to the distance covered and the elapsed time.

There are several different methods that may be used for arming/disarming of this feature. For example, the “Arm” button displayed in the screen of FIG. 7 may just be toggled to trigger the tracking function and start the timer. However, to prevent inadvertent arming, or prank usage of this feature by someone other than the owner of the mobile device, the module may require a passcode to be entered after toggling the arm button. The passcode may be the same passcode as the security code for the user's phone. Alternatively, since the user may already have the mobile device password protected to prevent its unauthorized use, a different password may be customized/entered for each individual trip made by the user, by assigning the passcode at the time of arming. After hitting the “arm” button in FIG. 7, the system may prompt the user for the passcode. A biometric recognition means for arming the feature may alternatively be used. The alarm can be armed/disarmed using a fingerprint, iris scan, retina scan, facial scan, blood type or any other biometric signature that may be a feature that is available on the device.

Alternatively, arming of the feature may occur by successfully answering a personal question presented to the user after the “ann” button is toggled, which may serve to verify the identity of the user. The questions can be randomly retrieved from a predefined library of questions.

A pattern code may alternatively be used for arming the feature, by imparting movement to either the mobile device or an extended feature of the device, such as a Bluetooth connected bracelet, in a pre-determined pattern, which may be measured by accelerometers.

Once the starting point and destination have been entered, and the feature is properly armed, it may automatically track and display the distances traveled and the elapsed time, as shown in FIG. 8. The module may display the travelers progress on the map in real time, and may also calculate an estimated time remaining (or an arrival time), based on the speed of travel. As seen in FIG. 8, if the user arms the feature but does not begin to walk immediately, or initially walks very slowly, the estimated time remaining (e.g., 44 minutes) may be greater than the time that was originally allotted for the trip (e.g., 43 minutes). The allotted travel time may be determined by the method of travel, i.e., walking, bicycle, train, or car, and it may also account for rush hour travel times, changing traffic patterns, weather, etc.

In the case of an unforeseen delay or divergence from the preferred route by the traveler (e.g., stopping to buy a cup of coffee), the system may send a message with a proposed alternate route, and/or a recalculated transit time. However, the system will need this change to be authorized and authenticated by the user before it can be made to the current trip, in order to determine if a valid detour is being initiated by the traveler, or if a kidnapping or other malicious activity is instead occurring. To authorize the change, the system may require the person to complete the same procedure for arming of this feature, as had been done at the start of the trip.

Another feature of the module is that it may require the traveler to check in periodically, to prevent the traveler from being accosted by one person, while another person continues to carry the traveler's device along the route displayed thereon to simulate safe progress, which would delay the sending of an alert that might otherwise provide assistance. In addition, or alternatively, the system may randomly send a message to the traveler to request authentication as to the holder of the device. Moreover, if the user is traveling too slowly, and will likely exceed the allotted time, the system may send a message requesting the person to authenticate that the extra time is needed, and that it was not due to an encounter that was perceived as potentially being risky and required extra caution on the part of the traveler.

For the scenario where the traveler knows in advance that he/she will be making one or more pre-planned stops at a location between the starting point and the destination, those stops may be entered as waypoints before the trip begins. As seen in FIG. 6, a provision may be made to enter the waypoints, similar to the entry of the starting point and the destination, so that the traveler can plan the entire day. Once the user enters the first way point, an option may be provided to enter another way point, so that as many intermediate way points may be entered as are necessary. As noted hereinabove, any variation from the preferred route between the starting point, the way points, and the destination, would require authentication and authorization for the re-routing.

Once the traveler has reached the destination, a couple different options may be used for disarming of the tracker. First, a settings option may be selected by the user so that disarming automatically occurs upon reaching the destination. However, to provide an added layer of security, a settings option may be selected so that he/she must signal the end of the tracking session, by manually disarming the feature by toggling the “disarm” button shown in FIG. 8. Manual disarming of the tracking feature may also require using the same method that had initially been used for its arming (i.e., using the passcode, when used initially). If the timer is not disarmed at the expected end of the trip, the panic alarm will be set off.

There may be a pre-programmed sequence of events by which the traveler and the system may interact, once the standard arm/disarm rules are violated, or if the traveler deliberately toggles the “panic” button shown in FIG. 8 at some intermediate point on the trip.

If the person encounters a dangerous situation while en route and toggles the panic button, the system may respond similar to a silent burglar alarm, and may trigger a request for confirmation that the user wants the panic message sent out to notify family members and/or to receive assistance from police/fire/medical personnel. The confirmation may be based on the predetermined user authentication method(s) that is/are chosen. The App user may have the option to enter a pass code to deescalate the severity of the situation, because it was a false alarm or because a potential threat had dissipated (e.g., two threatening individuals who began to confront the traveler became disinterested and eventually moved away). In this case, no further action would be taken by the system, unless the user again toggles the panic button, or the arm/disarm rules are otherwise broken.

However, if the App user responds to the request for confirmation of the panic alarm, by entering a preprogrammed duress code, an open escalate response would be triggered. This may include having the system send a second message to inquire if assistance from any one of the traditional first responders is appropriate (i.e., should the system request assistance from police, or the fire department, or emergency medical personnel, or a combination of those first responders). Also, because the person may be unable to respond to the second message due to the severity of the situation, the open escalate response of the system may include directing PTZ cameras, if available, to scan the location of the user's mobile device, and if warranted, sending a drone to also observe the area. The open escalate response may also include providing instructions to the first responders who may be en route, based upon the information received from the cameras and/or the drone(s). The provider of the security system may also retain security ambassadors throughout a city or region—ambassadors who may be able to provide various types of personal assistance in response to a panic signal sent from and confirmed by a user. The ambassadors may also carry smart phones or other such devices, and may thereby be directly notified by a server of the system, regarding a nearby person who may have triggered an alert indicating that they require assistance. The ambassadors may be employees of the service provider, or may be off duty employees, and/or sub-contractors. The App user may also have the option of selecting a particular security ambassador as their trusted agent. The extent of the escalation may be determined in advance by the settings selected by the user.

The App may also provide an option to the user who pressed the panic button, of further identifying the type of emergency, as seen in FIG. 9D, so that, if able, the person in distress may identify if it is a medical emergency, or if instead his/her personal security is threatened. If the user's personal security is threated, it may necessitate notifying both law enforcement and medical personnel. Failure to press either button may result in both types of responders being notified of the user's distress. If the user indicates that it is only a medical emergency, the server of the system may send notifications to other App users in the area, to solicit help from someone who may be in even closer proximity to the person in distress, than the security ambassador.

Another mode of the track me module is the provision of a panic alarm being sent upon the disconnection of a peripheral device. For example, the software program may be configured such that when a headphone is disconnected from an audio jack, the alert is activated. In an Emergency the user simply needs to disconnect the headphone and the panic notifications are sent off. The disconnection trigger may also be tied to the reception of a Wi-Fi Signal in a safe zone. If the Wi-Fi connection is broken, i.e., the person moves outside the safe-zone covered by the Wi-Fi signal, the duress may be triggered.

The system may provide several other methods to indicate that the person is under duress, which can then be treated as an escalated Panic alarm.

First, the person may enter a duress passcode, which may be a specific passcode that signals duress. Also, if a disarm passcode is requested by the system, and if the traveler is actually under duress at that point in time, then he/she may instead enter the duress code, and the system will indicate disarming, but will actual trigger a duress alarm to the backend. Therefore, if the traveler was accosted and intimidated into disarming the device, they may pretend to disarm the feature, while actually requesting assistance.

Second, the module may utilize speech recognition, and duress may be activated when a pre-determined trigger word or phrase, such as “Help Me,” is spoken into a microphone on the device, and recognized by the device. Alternatively, more discrete trigger phrases may be used, such as “The train is leaving Cleveland.”

Third, duress may be triggered by moving or shaking the mobile device in a pre-determined pattern, so that the onboard accelerometer may detect the pattern to initiate the duress trigger.

Fourth, duress may be triggered by exceeding a threshold distance between the wireless pairing of the mobile device with certain other technologies, such as a Bluetooth (or Wi-Fi) pairing, i.e., when pairing is broken, duress is triggered. Also, the paired device can trigger duress based on activating a specific button thereon.

Fifth, vital signs may be harvested from bracelets such as a fitness bracelet, or a security vest with bio monitoring, or any other vital sign monitoring device. The person can pre-determine the specific vital signs and thresholds which would trigger a duress alarm.

In the case where the traveler experiences duress, the map of the “track me” feature may provide the location of the closest first responders or security ambassadors that may be available to be routed toward the scene or a specific site during a particular incident.

In addition to the panic button within the “track me feature,” a generic panic button may also be provided for the user to utilize when they may not traveling from point to point, and may be exposed (i.e., while waiting to be picked up at a bus stop). The generic panic button may be designed to send an instant quick message with minimal user input. When setting up this feature the user may be provided with several configuration options from which he/she may choose. This may include a push-hold panic button, being a feature where the user pushes a button to arm the panic feature, and when the button is released, the panic message is sent. As there may be a case where the traveler determines that a potentially dangerous situation has been diffused and does not wish to release the button to send the panic notification, there will also be a provision for disarming without sending the panic message, such as by the entering of a passcode. Other means of triggering the generic panic button may be similar to that of the panic button within the “track me” feature, such as:

-   -   the capability to arm the panic mode with the headset connected         to the mobile device, and to trigger the panic message if the         headset is pulled out of the device;     -   the capability to train the device to listen for a specific         trigger word or phrase to send the panic message;     -   the capability to train the device to trigger the panic message         based on a specific memorized motion;     -   the capability to send the message based on the device's battery         life being drained below a threshold amount; and         The Panic message that may be sent may have the option of         listing any one of the following therein: the last numbers         dialed by the mobile device owner, the numbers of the most         recently received calls, the most recent texts messages sent,         and the most recent text messages received etc.

In the case where the user of the App may have been accosted, and was unable to trigger the panic button, once there is only a small amount of time remaining of the time allotted for the trip (e.g., 3 seconds remaining), the screen of the App may change to be as seen in FIG. 9C, as the device prepares to send an alarm signal. The device may also vibrate or beep to provide an aural alert to the user, in case the user was merely distracted and was not under duress. If so, the user may toggle the “I am Safe” button, otherwise the alarm will be sent as the time expires.

In another embodiment of the Track Me Module, as seen in FIG. 9, the user may be walking only a short distance (e.g., around the block of a bad neighborhood), and/or may simply expect to be loitering in the general vicinity of a particular location, such as when a worker leaves the building where he/she works, and walks down the street to stand and wait at a bus stop. In such instances, the person's personal safety may be uncertain for the period of time that they may have to wait alone at the bus stop, or may be walking around the block of a familiar neighborhood, and may therefore more aptly make use of the Track Me Timer shown in FIG. 9. If the person has an expectation of having to stand/loiter at the location for a certain amount of time, they may set the Timer to correspond to that time period. For example, if the bus stops at that particular bus stop every 15 minutes, the person may, upon reaching the bus stop, set the timer for 20 minutes. The timer may be set by entering an amount of time, or if the “Select Time” option is toggled, the display may change to display a list of standard time increments (e.g., 5 min, 10 min., 15 min., . . . 1 hour, 1 hour and 10 min., etc.) from which the user may choose. Once the time period is selected, the display may change to be as seen in FIG. 9A, in which the time remaining before an alert is sent, is prominently displayed on the screen (e.g., “19 Minutes Remaining”). Once the person reaches safety (e.g., boards the bus, or reaches the destination that may be around the block), he/she may toggle the “I am Safe” button, which may be a green-colored button that ends the time mode. If the person's safety is endangered and he/she fails to toggle the “I am Safe” button, once the timer has counted down to “3 Seconds” remaining, the message “Sending Alarm” may be displayed on the screen, and may be flashing and be yellow colored. In addition, the software may prompt the device to vibrate to bring the warning message to the user's attention, in case they are not in any danger, and have merely forgotten to toggle the “I am Safe” button. Once the time is exhausted (“ZERO TIME REMAINING”), as seen in FIG. 9C, the alarm will be sent, and will be so indicated on the screen.

In yet another embodiment of the Track Me module, the user may instead have the option of being tracked in relation to a Geo-fence, as seen in FIG. 6. The user may “Select” an existing Geo-Fence, or may create one using a map screen that may be displayed for the user. A plurality of existing Geo-Fences may be supplied with the App, such as University campus boundary, neighborhood boundaries, National Park boundaries, etc. If the user selects a university Geo-Fence boundary, the App may notify the user once he/she leaves the campus grounds, and may display a message onscreen with a red or red/blue button (e.g., a message stating, “You are currently outside of the campus area, please click this button to call 911”). Pressing the button would immediately dial 911 and send a pre-recorded message for help. While in the Geo-Fence track me mode, the App may send messages and reports to a predefined email address, SMS, or may autodial to a selectable individual (or any combination of the above), which may allow the App to work independently of a command center.

Blue-Phone-in-Pocket Module;

A variation of the Track Me module is the Blue-Phone-in-Pocket (bPip) module. The blue light emergency phone has been a college/university campus security staple for the past 25 years. Most colleges typically have 25 to 100 or more blue light phones distributed throughout the campus. However, the cost to install, maintain, and upgrade these systems from analog to digital, as well as integrating modem security measures therein is very high, especially when compared to the low level functionality afforded by the phones. Campus blue light phones feature a push-button which sends an alarm to whoever is monitoring the system. Two way communication is established at least while the person stands at that phone/location.

Because nearly every student on campus has a mobile phone and a data network, either cellular or campus Wi-Fi, when they are in trouble or need assistance, they may instead simply pull up the bPip module of their See it Send it App on their phone. Such use of the person's own device would typically be much faster than if the student had to first locate and then walk/run to the nearest blue light phone, if they are even able to proceed to the phone. When the App user pushes the blue button of the App on the screen of his/her phone to request help, the App may instantly record and transmit key information. Such information may include the student's name and contact information, the exact time that the button was pressed, the location of the user's device (via GPS, etc.) at the time they pushed the button. The App may also communicate this information to a command center (SOC).

The App may also communicate audio from the phone's microphone/speaker to potentially appraise emergency responders as to the current condition of the person in distress, and the presence of other people who may be in his/her vicinity. The App may also communicate visual data using the phone's camera (video or periodic snapshots, perhaps being roughly every 5 seconds) to further appraise emergency responders as to the situation surrounding the person in distress. The App may also record the audio and visual data, in addition to sending it to the SOC. The SOC Operator may therefore be able to immediately call the phone to establish communication and inquire the exact condition/status of the student, and/or find out what assistance is needed.

The SOC may also know what other persons may be in the area (e.g., other student users of the App, faculty members who may use the App, and emergency responders). This feature therefore provides multiple benefits, as the SOC may direct those students/faculty members to act in a responsible and an appropriately safe manner, which may depend upon the nature of the emergency.

Where a student (or even a faculty member) may only experience a stand-alone medical emergency and uses the App to request assistance (e.g., fell and broke a leg, person is experiencing symptoms indicating the onset of a heart attack, etc.) the SOC may ask any available students/faculty in close proximity to the person requiring assistance, to respond to the call for help, and render immediate assistance until emergency responders can arrive on the scene. To accomplish this functionality the App may thus communicate with a central server to continuously transmit and identify the location of each user via the GPS capability of his/her device. This permits the location of each user to be superimposed on a map, in relation to the position of the person experiencing the medical emergency, all of which may be available to the SOC. The SOC may then call one or more App users who may be in close proximity to the person in distress, to ask if any would provide assistance, and to direct them to the person in distress if they agree to render aid.

The system software also may automatically send text requests to other nearby students to ask for their assistance, and to direct them to the person in distress, as there may be 10 of 15 students nearby, which may require an excessive amount of time for the SOC to call to ascertain who may be willing to respond for a particular incident.

Alternatively, or addition to the SOC calling personally or the text messages, the server may automatically call several of the nearest App users and deliver a pre-recorded message requesting that the user provide assistance for the medical emergency, and with the server additionally providing specific directions at the end of the pre-recorded message fir each particular App user, to particularly direct each user to the person requiring assistance.

A reward system may also be used to encourage willing and able students to respond, such as a small cash award (e.g., $25) as a financial incentive to the first student to reach the person in distress, which may be determined by the GPS data received by the server and displayed on the map monitored by the SOC. To prevent fraud on the system, the person requesting assistance may also agree to a monetary fee for such emergency usage, where the fee may be used for the reward. This closed loop would serve to prevent two or more students from attempting to defraud the system to earn response fees for a staged incident.

In a different scenario, the App and the SOC may direct those students/faculty members to act very differently in order to be responsible and safe, which may occur when the nature of the emergency is dangerous to them and/or to other person's in the area. Such an emergency may just be a physical altercation between two individuals, or may be when a shooting incident occurs on campus or in a community, in proximity to the App users, particularly when the shooting is ongoing. In this case the APP may send a warning to the App user to direct them away from the shooting incident. Although it is common to send a text message as a warning for certain events, particularly meteorological events (e.g., a flood alert), such text messages quite often go unnoticed by students for a substantial period of time, because students often send/receive hundreds of text messages a day, and because the students may be in the middle of class and may be waiting until the end of class to review any messages received. To avoid the risk that a student would delay receiving such an alert, the App may be set up to use the speaker of the user's device to provide a loud (e.g., full volume) aural warning (e.g., “Warning—Danger, Shooting in Progress—exit campus immediately avoiding Building X”). The aural message may repeatedly be announced on the device until the user acknowledges the alert by toggling a button on the screen of his/her device. Alternatively, the aural alert may continue at a reduced volume, until the person has traveled away from proximity to the perceived danger zone (e.g., moves to be a threshold distance away, e.g., at least a quarter of a mile away, from GPS location of the shooting incident, or the shooter's current location if on the move). Because such an event may persist for a lengthy period of time, as in the 2007 shooting spree at Virginia Polytechnic Institute which took two hours to be finally resolved, students that may have received an initial warning text, may resume their usual activities and may be less aware of the continuing danger. Therefore, the App may also provide additional warnings to those App users who may be immediately outside of the threshold safety distance (i.e., less than a second threshold distance away, such as less than a half a mile away but more than a quarter mile away), and who may be in transit and heading generally toward the shooter's location. To better appraise the App user of the potentially dangerous direction of travel, the App may send a series of periodic warning texts identifying the shooter's location, such as a text message every 5 seconds, or every 10 seconds, etc., until the App user ceases movement towards the shooter.

The App may similarly utilize one or more textual warning message for other categories of events (e.g., non-violent criminal activity such as reported thefts, or natural disasters such as tornadoes, earthquakes, severe lightning storms, etc.).

In general, some of the benefits of the bPip module are quicker reporting and identification of the problem; richer, more accurate and timely data as well as real time updates of that data; provision of situational awareness data (who is around there), faster possible response time to the location to mitigate the event, etc. The (bPip) module provides students better access to an emergency device (their own phone) at a lower overall cost than the blue phone, with better situational results. The (bPip) module may also send messages and reports to a predefined email address, SMS, or a selectable individual, or any combination of those options, which may permit the module to work independently of the command center.

Incident Reporting Module;

The mobile App may include an incident reporting module, which may have the capability to report the details of an incident, including the category of the incident, the location, a brief description of the incident, and any related pictures or video that may have been captured.

With respect to the category of the incident, the user may be able to choose from several standard categories. The module may also be utilized by a particular organization/client (i.e., a neighborhood watch group), and that organization may create their own categories for their users to select from, such as: Suspicious Activity, Crime in Progress, Maintenance, etc.

With respect to the location of the incident, some standard location choices may be provided, such as “Use My Current Location.” Also, the client may create their own locations for their users to select from, such as: “Parking Lot A.” or “Admin. Building.” or “Penn Station,” etc.

With respect to the description of the incident, a free form text field may be provided for the user to enter a textual description. This may be supplemented with pictures/video, for which several options may be provided. The App user may have the choice to utilize the onboard camera of the device to take new photos or videos, or may instead select existing photo/video files. Once the photo or video file is selected, the application may start uploading the file to a temporary area on a server of a system administrator, while waiting for the command to submit the incident. Once the incident is submitted, the textual description and other data may be submitted immediately, even if the file upload is not complete. The file upload may follow the data, and once the upload is complete, the incident data on the server may be updated. The incident data may also include three dimensional GPS coordinates, as well as unique identifiers from the device, and the identity of the user that was logged as having submitted the incident.

Person of Interest Tracker Module;

When an incident does occur, and the App user was able to obtain either a photo or some video that includes the person responsible for the incident, they may utilize this feature to enable tracking of that person. With this module, the user can identify a specific person in a picture or video that includes more than one person. The App user may identify the person by drawing an outline around them using a stylus, or just using their finger. This module allows the user to create the initial reference files which can be sent to the system administrator, which then can also be imported into various other third party systems, including those utilized by law enforcement agencies. This feature can also be used to identify “objects” of interest, such as bags, cars, animals, etc., and may also be used to identify “areas” of interest (e.g., a particular storage unit at a self-storage center, etc.). As a result of drawing an outline around a person or an object of interest, the App may utilize an algorithm to create a unique digital signature of the person/object. The algorithm may use many factors to create the signature, including but not limited to; curvature of the suspect's spine, the person's walking gate, color contrast, aspect ratio, size, etc.

This module may also include the capability to pre-process a unique digital signature from the video stream or picture, so that it can be checked and cross referenced with databases from third party systems and matched against signatures generated by their databases for the identification of persons (or objects and/or the finding of locations). The user's mobile device, which may be referred to herein as an edge device (i.e., they act as an entry point for data), may be loaded with specific algorithms to pre-process information on the device CPU, before sending it to the main system of the administrator. This may be very advantageous when hundreds and even thousands of loads are taken care of individually on multiple edge devices before sending to the main system for additional processing.

I.D. Verification Module;

This module may include the capability of capturing pictures or data from or about individuals, and of comparing the data to data within existing internal databases or third party databases for matches. This module may be capable of taking pictures of a person, or their I.D. card, or employee badge, a bar code, a QR code, etc., and may perform optical character recognition (OCR) on the image, and may cross reference the data with the database of a third party access control system (ACS). Upon a match in the data or a positive identification of the individual person, the system may capture the data from the ACS and send it back to the user's mobile device. A photo of a person may be analyzed by a facial recognition algorithm to compare it against a database of images.

The module may have access to certain police databases where, with special permission, access to limited information on specific individuals may be provided. The system administrator may correlate information gathered on specific individuals and utilize the information as an internal knowledge database.

Mobile Profiler to Create Composite Images;

The mobile profiler module may provide the user with the capability of creating an image to send as a representation of an individual that they are trying to describe. The mug shot sketcher portion may provide the capability of selecting facial features to create a “mug shot.” The Avatar Creator portion of the module may permit creation of an avatar by selecting from a series of choices, such as male or female, shirt color, pants color, etc. The mobile profiler module may also permit collaborative creation of the avatar, as it may be shared with other App users. Thus the avatar created by one user may be modified or improved by a second App user (e.g., “the person's nose was a little bigger”), and it may also be updated by subsequent users (e.g., “now he is wearing a red jacket . . . ”). This may be very useful in many different scenarios, including, for example, where a suspect robs a store and runs out past a group of people who may thereafter each individually and then collaboratively use the module to sketch an avatar that represents the suspect. Even in the situation where two or more people separately create an avatar to represent the suspect and do not thereafter collaborate, the system may utilize an algorithm to combine features of the two avatars to form a collaborative avatar. The system may also be capable of using that 3d avatar to search through video to identify anyone fitting that profile, which may be done in real-time or near real time.

Drone Assist Module;

This module offers features/functionality for utilizing drone assistance, which is particularly advantageous during live pursuit over varying geographical configurations where there crowds. The module may permit tracking via GPS & Wi-Fi, of both people and assets. Phones or mobile devices emit signals while looking for GPS or for Wi-Fi connection, even if not connecting to specific Wi-Fi. The drone can identify the particular individual by the specific signal given off by their phone, and may track them by tracking the signal. Once a suspect, asset, or other person of interest has been identified and they run into a crowd, a building, a tunnel, tree cover, etc., where it may be difficult to track them visually, the drone can still track and identify that person by the signal given off by their mobile device.

The module may also be configured to permit auto tracking using onboard video, to be capable of tracking dynamically while on the move. The module may also be able to identify and track individuals by the signal broadcast by their mobile devices to continually track with the capability to hand off to another drone, and to share the information with any other modules herein. Different hovering patterns may be selected for the drone when tracking an asset or another person.

As an example, an asset (e.g., a police officer, security guard, etc.) may be chasing a suspect on foot or in a vehicle. A drone may track and follow the chase visually from the air, and may also be sending that video to the App running on the mobile device of the asset. If the suspect disappears around a corner or takes cover somewhere, and the asset becomes uncertain of the direction the suspect went and/or the potential danger posed by the situation, he/she can look at his mobile app and watch the live video from the drone. The video may inform the asset of the direction taken by the evasive suspect, and whether the suspect may be waiting around the corner with a weapon pointed in the direction from which the asset may need to continue the pursuit. The drone may also provide the asset, through the App on his/her mobile device, a local map upon which the position of the suspect's mobile device is located.

Accessibility of Functionality Using Google Glass;

The user's mobile App may be coded to be capable of being utilized with Google Glass. The user may therefore have the capability to scan and search using the Google Glass technology, and obtain photographic images, which may be used in conjunction with the above described modules of the “See It Send It” platform to process the images and obtain live data. Real time guidance may be provided to the user to access the functionality of the “See it Send it” mobile platform using their Google Glass. The Google Glass may be used for controlling and uploading pictures and video. A dashboard capability may be provided to guide the user through the functionality in Google Glass. The dashboard may permit selection of a fixed camera to be monitored by the user, and may also permit selection of a pan/tilt/zoom (PTZ) camera configured to follow IR pulse emissions. The dashboard may also permit selecting of live drone feed video in theater while in pursuit of person of interest, as well as the scrolling of bulletins to users while on the go.

Wearable Devices;

The App of the present invention may be configured to coordinate with certain wearable devices that may communicate critical data through the mobile App to the control center of the administrator. One wearable device may be a security vest that may be able to transmit vital signs and impact data through the mobile App to the administrator.

Bail Check-In Module;

This module is intended for the bail bond industry and allows for periodic check in. This module may provide an opt-in feature where bail is given with the condition that the suspect uses the application to check in as required. The module may also be used for where a prisoner is released on parole, and that parolee is required to routinely check in with a parole office. The terms “suspect” and “parolee” are therefore intended to be used interchangeably herein. The key features of the module are:

User Check-In Screen—This aspect of the module is configured for scheduled check-ins, and an automatic alert generated to remind the suspect to check in as required. The module also provides for triggering a random check in by the suspect. When the suspect responds to the alert and performs the required response or entry of information, the suspect's GPS location may also be sent back to system.

Authentication—This aspect of the mobile app may be configured to authenticate the identity of the suspect/parolee using one of several different methodologies, i.e., Random security questions, voice pattern recognition based on randomly generated phrases, fingerprint identification, an iris scan, a retina scan, a facial scan, blood type, or any other biometric signature that is an available feature of the device.

Stealth Tracking—This aspect of the module is configured to inform the bail bond company as to the location of the suspect, using either a random ping to the mobile device, or a periodically timed ping. This feature may be put into effect when a bail applicant opts in to the program during his or her bail application. If the suspect violates the terms and conditions set by the bail requirements, an SMS message is sent to the subject, and the GPS location of the suspect will immediately be sent during the interaction to the bail bond company.

Auto Ping—This aspect of the module is configured to automatically ping the mobile device to obtain its location, without any end user intervention, to ensure that the app is online and functioning properly, and that it has not been de-activated.

Geofencing Screen—This aspect of the module may provide an on-screen map image of the region surrounding the suspect, which may include a customized geographic perimeter within which the suspect is required to remain, in order to ensure that the terms and policies of bail are being adhered to. It may also include one or more pre-defined restricted zones therein, into which the suspect/parolee is prohibited from entering, such as a school zone, etc.

Call Recording—This aspect of the module may provide the capability to record inbound and outbound calls made with the device if the suspect/parolee is in violation of the bail condition.

Bracelet Pairing—This aspect of the module may provide the capability to functionally pair auxiliary devices to the mobile phone using Bluetooth or Wi-Fi. Suitable auxiliary devices may include a leg or wrist security bracelet. Once paired, the authentication mechanism will utilize the pairing with the auxiliary device secured to the suspect, to ensure that the suspect is physically located in acceptable proximity to the mobile device.

Landline Caller ID Using Access Code—This aspect of the module may provide additional verification of the suspect/parolee location by messaging the person to call a dial back number using a land line. The system may verify the land line location through the phone carrier to further validate the suspect's current location, by corroborating that the landline and the mobile device are co-located.

Authentication—This aspect of the module may provide authentication of the identity of the parolee using multiple methoxlologies, i.e., random security questions, finger print using sensor on smart-phone, iris scan, retina scan using a camera on the phone, or voice pattern recognition based on randomly generated phrases.

Backend Engine:

A software back end engine in the cloud ingesting data from all the edge devices may be provided. Data captured or created by the user may be stored on and pre-processed by his/her mobile device, by the software of a Mobile Engine installed and running thereon. The information and/or attachments may then be sent via wireless communication through a network into the Backend Engine which has processing power and storage via servers and databases within its infrastructure. The information submitted may be processed further and stored. The Backend Engine may be dynamic with load balancers, automatic provisioning, sharding, and clustering for additional capacity. The Backend Engine may then send information back to the mobile device's Mobile Engine where additional commands can be executed or data gathered and sent back to the Backend engine. This iterative process may repeat multiple times while executing commands and working within an infrastructure consisting of the Backend Engine, one or more Mobile Engines, and mobile device users as well as external and internal databases and data stores.

Filtering and processing functions may be programmed, including but not limited to: Video, Audio, Text, and Correlation. The back end engine, which may also include a Geospatial GIS engine, may connect to third party databases and third party systems such as Google etc. The backend engine may also be configured to do auto-stitching of video and pictures on a geographical interface. The back end engine may also include the following:

Search Analytics—The backend engine may have the capability to process information in real time using video analytics to identify items including but not limited to:

-   -   Color—i.e., finding people wearing blue jackets and black pants;     -   Vehicles—by license plate number or specific car colors;     -   Location—filter search by geographical location;     -   Key words—text analysis such as “suspicious bag”     -   Facial Recognition—By matching facial signature and or facial         features in a database in comparison to what is being uploaded.

Geo Fencing—The backend engine may have the capability to dynamically and in real time create and section off a zone on a map, and provide and alert if someone, or some type of incident, is inside or outside of the boundaries. The engine is configured to create rules around zones for the occurrence of such incidences.

Situator Interface—the engine may accommodate bidirectional communication and interface into Nice Situator PSIM system (Physical Security Information Management, by TM Group Technology Management), i.e., sending audio, video, pictures and incident information into a Nice Situator and vice versa. The engine may also push information from the Situator to the mobile app users.

Altitude Calculation—The backend engine may also have the functionality to track and locate a person using latitude and longitude coordinates, and also altitude. The back end engine may operate to calibrate the detected altitude with the floor number of a particular building, i.e., it may locate a person, giving the street address, building number, and the floor number.

Multi-Functional Pre-Processing Information Module;

This module may provide Application and software intelligence running on the mobile device that may be used for pre-processing of both structured and unstructured information, i.e., video, audio, text. Some features of this module include, but are not limited to, the following:

Dual Encoding—The mobile engine may be able to take video and audio that was captured to store high resolution copy, and encode and transcode the video to a high efficiency format so that the data can be uploaded in the most efficient manner, as quickly as possible using the minimal amount of resource, especially bandwidth, and in an automatic fashion. The back end engine may collaborate with the mobile engine to select the most efficient stream available for uploading (i.e., Jpg, mjpg, mpg4, h.263, h.264, h.265, etc.). The encoding/transcoding can optimize the video data by 2 methodologies:

-   -   1) Frame rate dilution, i.e., 30 fps to 15 fps to 7 fps to 3 fps         to I fps.     -   2) Resolution drop, i.e., 2 mp to 1 mp to 4 cif to 2D to CIF.

Edge Analytics—Pre-Processing using the edge device CPU with specific algorithms is also provided. The user's mobile device, also referred to as the edge device, can be loaded with specific algorithms to pre-process information on the device CPU before sending it to the main system. Examples include video analytics, facial recognition, audio analytics and text to speech and speech to text.

Smart Transmission—Smart transmission gives the functionality to start pre-uploading images and other data into a temporary file on the server until the send command is executed. Smart transmission may also include sending low resolution files quickly, and the higher resolution files as a follow up, or when bandwidth availability allows. The application may send data using Wi-Fi, cellular, or other network connectivity available, or any combination of available connections.

Authentication Biometrics—the pre-processing information module may process biometric data, including, but is not limited to, fingerprints, iris scans, retina scans, facial scans, a blood type, or any other biometric signature, using the features available of the particular mobile device.

Voice—the pre-processing information module may perform voice pattern recognition and voice matching for authentication using predetermined phrases or random phrases. This feature may also be used to pre-process data stored on any recorded voices.

Unique Personal Data—the pre-processing information module may provide an automatic list of questions from a library of pre-populated personal questions.

POI, Object, or Area Search on Video/Pictures—using this capability of the pre-processing information module, the user can identify a specific POI (Person Of Interest) or an object in a picture or video, and select the person/object by drawing an ellipse or square or any other specific outline around them. This feature may allow the user to create the initial reference files that can be sent to the main system, which then can also be imported into various other third party systems. This feature can also be used to identify “objects” of interest such as bags, cars, animals, as well as outline “areas” of interest.

Data Destruction—the pre-processing information module may provide the capability to delete data after being viewed and once the parameters are met. An additional option may be provided to multiple over-write upon the sectors that the data was originally written upon. There may also be an option to do a delete and multiple overwrite at both the source and destination.

Data Authentication—the pre-processing information module may be configured to authenticate that the data sent from a specific mobile device was actually sent from that particular mobile device. A unique watermark may be generated based on the device serial number and ID. This feature may also provide for maintaining the chain of custody of the data.

Secure Transmission—The mobile engine may be configured to send information in an encrypted and secure manner to the back end engine and associated cloud.

Fan Experience Module;

This module may provide information for fans attending an event at a stadium, and may also provide security information to keep them aware and safe while approaching and in attendance at the venue. Some features of this module include, but are not limited to, the following:

Parking assist/Parking Lot Section—This aspect of the module may provide the user with up-to-date information as to where parking spaces are still available. Moreover, once the person finds and parks in an available parking spot, the App may identify and store the location of their parked car, so that it may provide direction after the event to help the person later find his/her way back to their car.

Best Queue—This aspect of the module may tell the fan where to enter the stadium for the shortest queue, and may give directions based on a current position and crowd conditions (e.g., “Entry at lane F—walk forward 450 feet and turn right . . . ”).

Seat Find—This aspect of the module may tell the fan the best way to proceed to their seat, based on a current position and crowd conditions

Social media alerts—This aspect of the module may provide the fans with alerts based on social media postings, which may warn the fan that some hazardous/dangerous activity may be going on, to warn them to move away from or to avoid a specific section (e.g., “fight breaking out in Section C . . . ,” or “ice being thrown on steps between Sections E and F,” etc.).

Got-to-Pee—This aspect of the module may provide the fan with directions to the nearest bathroom, based on a current position and crowd conditions, and may also evaluate and appraise the user of congestion/wait times.

Concession Stand/Beer Stand/Kiosk—This aspect of the module may provide the fan with directions to the nearest Concession Stand/Beer Stand/Kiosk, based on a current position and crowd conditions, and may also evaluate and appraise the user of congestion/wait times.

Vendor Request—Asks what is needed/requested and based on section . . . takes collective consensus—sends vendors with the right mix and ratios (e.g., beer/soda, Chips/Popcorn, etc.).

Food Order—This aspect of the module may provide a full menu of food items available so that the fan can utilize one of the following:

-   -   ReadyOrder—submits the food order so that the selections may be         prepared and ready when they go to pick it up and pay at the         kiosk/window.     -   FullServ—permits the fan to pay for the food order online and         have the order delivered directly to their seat.

Jumbotron Submit—This aspect of the module may permit the fan to submit pictures (e.g., selfies) and/or video so that it may be displayed upon the jumbotron in the stadium.

Sell Time/Auction Time—This aspect of the module may permit the fan to pay for or bid on a segment of time, during which their picture or video submission would be displayed on the jumbotron.

Game Interact—This aspect of the module may permit the fan to pay for or bid on a segment of time, during which they may launch interactive games on the jumbotron/win video position, etc.

VIP Access—This aspect of the module may permit the fan to receive internal communications from the organization that may be hosting the event at the stadium (e.g., the NFL/NBA/MLB, etc.), such as dugout pictures, microphone feeds, player pictures, etc.

Entry Exit—This aspect of the module may help the fan to find the best or quickest exit out of the venue, and may provide directions based on a current position and crowd conditions.

Emergency Exit—Gives emergency evacuation information and directions based on a current position and crowd/safety conditions.

Panic—may include the same functionality as the main app but is embedded into the fan experience module.

Incident Reporting—may include the same functionality as the main app but is embedded into the fan experience module.

Software of the present invention may run on a suitable computing device, such as a server, a tablet, a cell phone, or other mobile smart device, so a description of such an accessorized exemplary computer system is hereinafter disclosed, even though a particular embodiment may not require all of the described components. Exemplary computer system 200 (i.e., a client device associated with a particular user) is shown schematically in FIG. 10, and which may comprise computing unit 201 interacting with external peripherals 202, such as a separate touch screen display 244, and interacting with network resources 203, including use of the internet 261, and other computers (or other client devices or a server), which may be a laptop computer 262 (i.e., a second client device associated with a second user), a smart phone 263 (i.e., a third client device associated with a third user), a server 264, etc.

The computing unit 201 may include a data bus 224 for communicating information across and among various parts of computing unit 201, and a central processing unit, which may be a microprocessor (hereinafter “processor” or “CPU”) 222 coupled with a bus 224 for processing information and performing other computational and control tasks. Computing unit 201 may also include a volatile storage 225, such as a random access memory (RAM) or other dynamic storage device, coupled to bus 224 for storing various information as well as instructions to be executed by processor 222. The volatile storage 225 may also be used for storing temporary variables or other intermediate information during execution of instructions by processor 222. Computing unit 201 may further include a read only memory (ROM) or an erasable programmable memory (EPROM) 227 or other static storage device coupled to bus 224 for storing static information and instructions for processor 222, such as basic input-output system (BIOS), as well as various system configuration parameters. A persistent storage device or non-volatile memory 226, such as a magnetic disk, optical disk, or solid-state flash memory device may be provided and may be coupled to bus 224 for storing information and instructions.

Computing unit 201 may be coupled via bus 224 to an integral display 221, possibly a touch-screen display, for use in displaying information to a user. If desired, computing unit 201 may be coupled via bus 224 to an external display screen 244. An external input device 243 (e.g., a standard keyboard) may be coupled to bus 224 for communicating information and command selections to processor 222. A cursor control device 242, such as a mouse, a trackball, or cursor direction keys, may be used for communicating direction information and command selections to processor 222 and for controlling cursor movement on display 244. An external storage device 241 may be connected to the computing unit 201 via bus 224 to provide an extra or removable storage capacity for the computing unit 201, which may be used to facilitate exchange of data with other computer systems.

Some of the techniques herein may be performed by computing unit 201 in response to processor 222 executing one or more sequences of one or more instructions contained in the volatile memory 225. Execution of the sequences of instructions contained in a non-transitory memory may cause processor 222 to perform the process steps described herein. In alternative embodiments, specific hard-wired digital circuitry may be used in place of or in combination with, software instructions to implement the invention.

The term “computer-readable medium” as used herein refers to any medium that participates in providing instructions to processor 222 for execution. The computer-readable medium is just one example of a machine-readable medium, which may carry instructions for implementing any of the methods and/or techniques described herein. Various forms of computer readable media may contain one or more sequences of one or more instructions for the processor 222 to execute, including non-volatile media (storage device 226), and volatile media (storage device 225). Common forms of computer-readable media include, for example, a floppy disk, a hard disk, magnetic tape, or any other magnetic medium, a CD-ROM, a flash drive, and a memory card.

The computing unit 201 may thus also include a communication interface, such as network interface card 223 coupled to the data bus 222. Communication interface 223 may provide a two-way data communication coupling to a network link that may be connected to a local network. For example, communication interface 223 may be an integrated services digital network (ISDN) card or a modem to provide a data communication connection to a corresponding type of telephone line, or it may be a local area network interface card (LAN NIC) to provide a data communication connection to a compatible LAN.

Network link 223 also typically provides data communication to other network resources. For example, the network link may provide a connection over the internet 261 to the world-wide-web. Thus, the computing unit 201 can access resources located anywhere using the Internet 261. Also, the computing unit 201 may also be accessed by, or communicate with, other computers (e.g. 262), or another smart device (e.g., smartphone 263), generally with permission, and which may be located anywhere with access to the internet 261.

The examples and descriptions provided merely illustrate a preferred embodiment of the present invention. Those skilled in the art and having the benefit of the present disclosure will appreciate that further embodiments may be implemented with various changes within the scope of the present invention. Other modifications, substitutions, omissions and changes may be made in the design, size, materials used or proportions, operating conditions, assembly sequence, or arrangement or positioning of elements and members of the preferred embodiment without departing from the spirit of this invention. 

I claim:
 1. A computer-implemented method comprising: configuring a plurality of client devices for continuously transmitting its respective geographic location wirelessly over a network to a server; configuring the server for continuously monitoring the geographic location of each of the client devices; configuring each of the plurality of client devices for selectively transmitting an alert from the respective device to the server; configuring the server for identifying when one of said client devices is transmitting the alert; configuring the server for transmitting a message to a selective one or more of said plurality of client devices being in proximity to the one client device transmitting the alert; further comprising: configuring the server to notify emergency medical responders when the one client devices transmits an alert for a medical emergency; configuring the server for to call and transmit a pre-recorded voice message to each of said plurality of client devices being in proximity to the one client device of the user requiring assistance; and configuring the server for providing respective directions for each of the client devices in said proximity to the one client device of the user requiring medical assistance, to respectively proceed to the one user requiring medical assistance; further comprising: charging a fee for transmitting of the alert for the medical emergency by the one client devices; and paying a reward to a user of a first client device of said plurality of proximal client devices, that reaches the user requiring medical assistance.
 2. The computer-implemented method according to claim 1, further comprising: configuring the server to notify law enforcement officials when the user of any of the plurality of client devices transmits an alert for a physical altercation; and configuring the server for sending a text message to all of the other client devices for identifying the location of the physical altercation.
 3. The computer-implemented method according to claim 1, further comprising: configuring the server for monitoring local police frequencies and for performing audio analytics for key words indicating an occurrence and a location of a shooting incident; configuring the server for sending a text message warning any of the plurality of client devices outside of a first threshold distance away from the location of the shooting; and configuring the server for triggering a continuous aural warning using a speaker of each client device being within said first threshold distance away from the location of the shooting.
 4. The computer-implemented method according to claim 3, further comprising: configuring the server for monitoring a direction of travel of any of the plurality of client devices outside of said first threshold distance away from the location of the shooting, but being within a second threshold distance away, said second threshold distance being greater than said first threshold distance; and configuring the sever for providing periodic text messages to the direction-of-travel-monitored devices that are currently traveling toward the location of the shooting.
 5. The computer-implemented method according to claim 1, further comprising: configuring the server for associating a geographic location of each of a plurality of client devices with a respective local police band broadcast; selectively transmitting the respective local police band broadcast to each said client device; configuring the server for performing audio analytics of each respective local police band broadcast for identifying one or more desired key words.
 6. The computer-implemented method according to claim 1, further comprising: configuring each of the plurality of client devices for push-to-talk voice transmitting and receiving over the network, with one or more other said client devices, when within a set radial distance away.
 7. The computer-implemented method according to claim 6, further comprising: receiving conventional radio communications; configuring the server for re-encoding the received conventional radio communications and for transmitting the re-encoded radio communications over the network; selectively receiving the transmitted re-encoded radio communications by a user of one of said plurality of client devices.
 8. The computer-implemented method according to claim 6, further comprising: configuring each of the plurality of client devices for respectively adjusting the set radial distance for said transmitting and receiving.
 9. The computer-implemented method according to claim 8, further comprising: configuring each of the plurality of client devices for displaying an interactive map, and for positioning thereon of icons respectively identifying each of the plurality of client devices being within the set radial distance and currently transmitting and receiving over the network.
 10. The computer-implemented method according to claim 8, further comprising: configuring each of the plurality of client devices for identifying each of the client devices currently transmitting and receiving over the network, by using speech bubbles in conjunction with said icons.
 11. The computer-implemented method according to claim 1, further comprising: configuring each of the plurality of client devices for entering of a desired time period; and configuring each of the plurality of client devices for automatically transmitting an alert after the entered period of time expires.
 12. The computer-implemented method according to claim 1, further comprising: configuring each of the plurality of client devices for entering of a respective destination for a trip, for entering of a starting point for the trip, for selecting of a mode of transportation for the trip, for indicating the start of the trip; configuring the server for identifying a preferred route for the trip entered by the one of said client devices, based upon: a distance of the trip, a crime rate for areas between the starting point and the destination, and based on the mode of transportation; configuring the server for calculating an allotted time for the trip, based on the mode of transportation, the distance, the current traffic pattern, and the weather; configuring the server for tracking each of the client devices during a respectively entered trip; and configuring each of the plurality of client devices for transmitting the alert to the server when the client device is deviating beyond a threshold amount from the preferred route or from the allotted time for the respectively entered trip.
 13. The computer-implemented method according to claim 12, further comprising: configuring each of the plurality of client devices for modifying the preferred route and the allotted time when authorized by a user of the respective client device.
 14. The computer-implemented method according to claim 13, further comprising: configuring each of the plurality of client devices for modifying the mode of transportation, the preferred route, and the allotted time, when authorized by a user of the respective client device.
 15. The computer-implemented method according to claim 12, further comprising: configuring each of the plurality of client devices for identifying the start of the trip by one or more of: by manually toggling of a start button; by entering a passcode; by answering a security question from a library of such questions; by using a biometric identification means; and by imparting movement to the client device in a pre-determined pattern.
 16. The computer-implemented method according to claim 15, further comprising: configuring each of the plurality of client devices for displaying a map indicating the preferred route for the trip, and real-time progress as to elapsed time, time remaining, and distance remaining.
 17. The computer-implemented method according to claim 16, further comprising: configuring each of the plurality of client devices for prompting the user of the respective client device to approve a projected delay for a respectively entered trip that is deviating beyond the threshold amount from the preferred route or from the allotted time.
 18. The computer-implemented method according to claim 17, further comprising: configuring each of the plurality of client devices for accepting the approved delay only by the user performing one or more of: re-entering the passcode; answering another security question; by using the biometric identification means; and by imparting the pre-determined pattern of movement to the client device.
 19. The computer-implemented method according to claim 17, further comprising: configuring each of the plurality of client devices for randomly requiring authentication of the user, by the user performing one or more of: re-entering the passcode; answering another security question; by using the biometric identification means; and by imparting the pre-determined pattern of movement to the client device.
 20. The computer-implemented method according to claim 12, further comprising: configuring each of the plurality of client devices for entering of one or more intermediate waypoints between the starting point and the destination; and configuring the server for identifying a preferred route and for calculating an allotted time for the trip by furthermore including the one or more waypoints.
 21. The computer-implemented method according to claim 12, further comprising: configuring each of the plurality of client devices for terminating the trip without sending the alert, upon occurrence of any of the following: reaching the destination; and toggling a disarm button in conjunction with one or more of the following: re-entering the passcode; answering another security question; by using the biometric identification means; and by imparting the pre-determined pattern of movement to the client device.
 22. The computer-implemented method according to claim 12, further comprising: configuring each of the plurality of client devices for triggering the alert by any of the following: manually toggling a panic button; disconnecting of a peripheral device; moving the client device in a pre-determined pattern; moving outside of a safe zone delineated by reception of a WiFi signal; monitoring if a vital sign of the user exceeds a predetermined threshold; determining a battery charge level of the client device being drained below a threshold battery charge level; speaking of a trigger word by the user; and configuring the server for notifying a family member of the user and for notifying law enforcement officials, and for providing the last numbers dialed by the client device, the phone numbers of the most recently received calls by the client device, the most recent texts messages sent and received by the client device.
 23. The computer-implemented method according to claim 12, further comprising: configuring each of the plurality of client devices to prompt the user for acting to confirm the alert or to rescind the alert, with rescinding of the alert requiring authentication of the user, by the user performing one or more of: re-entering the passcode; answering another security question; by using the biometric identification means; and by imparting the pre-determined pattern of movement to the client device.
 24. The computer-implemented method according to claim 23, further comprising: configuring the server to direct one or more local cameras at the user of the respective client device, when the user does not confirm the alert or rescind the alert; configuring the server to direct one or more drones to observe the user of the respective client device, when the user does not confirm the alert or rescind the alert; and providing information received from the cameras and the drones to emergency responder while en route to the user. configuring the server for routinely sending a check-in reminder message to the client device; configuring the client device for transmitting a defendant response for the routine check-in, to the server; configuring the server for randomly sending a check-in message to the client device; and configuring the client device for authentication of the defendant. 